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Article
Volume 12, Issue 4, 2022, 5458 - 5478
https://doi.org/10.33263/BRIAC124.54585478
Development and Validation of Novel Analytical
Simultaneous Estimation Based UV Spectrophotometric
Method for Doxycycline and Levofloxacin Determination
Yogesh N. Gholse 1,* , Dinesh R. Chaple 1 , Rahul H. Kasliwal 1
1 Department of Pharmaceutics, Priyadarshini J. L. College of Pharmacy, Electronic Zone Building, Hingna Road, MIDC,
Nagpur- 440016, Dist-Nagpur (M.S.) India
* Correspondence: [email protected] (Y.N.G.); Scopus Author ID: 54890775600
Received: 8.07.2021; Revised: 25.09.2021; Accepted: 28.09.2021; Published: 19.10.2021
Abstract: The thorough literature study uncovered that none of the most perceived pharmacopeias or
any journals includes a method for simultaneous estimation of Doxycycline and Levofloxacin in
combination by UV/Visible spectroscopy. So, it was felt fundamental to build up a system that will
serve as a solid, precise UV technique for the simultaneous estimation of Doxycycline and
Levofloxacin. DOXH and LVXH showed λmax at 273nm and 287nm respectively, and iso-absorptive
point at 280nm in Phosphate buffer pH 6.8 prepared in Water: Methanol (80:20) dissolvable solvent
system. Beer Lambert's law obeyed by both drugs within the concentration range of 2-20 μg/ml & r2
values of 0.9999 and 0.9998, which shows the good linearity. The method has been validated
statistically and quantitatively regarding linearity, precision, LOD, LOQ, accuracy, and specificity
according to the ICH guidelines. LOD for DOXH and LVXH were found to be 1.41 and 0.63 μg/ml,
the LOQ was 4.30 and 1.92 μg/ml, respectively. Percent recovery at recovery level of 80%, 100% &
120% for DOXH was found to be 99.7, 99.66 & 99.69 & for LVXH 99.58, 99.66 & 99.63 respectively.
Intra-day, Inter-day & precision analysis by different analyst was found to be 0.767, 0.563, 0.440 %RSD
for DOXH & 0.507, 0.532, 0.708 % RSD for LVXH. Sandell's sensitivity was discovered to be
adequate, and this shows that extremely less measure of the two medications can be successfully
recognized by this technique. Finally, it was concluded, the developed & validated method was helpful
and appropriate for regular quality analysis and simultaneous determination of drug products containing
DOXH and LVXH in combination.
Keywords: doxycycline hyclate; levofloxacin hemihydrate; synthetic mixture; simultaneous
estimation; UV- Visible spectrophotometric method.
© 2021 by the authors. This article is an open-access article distributed under the terms and conditions of the Creative
Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
1. Introduction
Doxycycline hyclate (DOXH), C24H33ClN2O10 (CAS No. 24390-14-5), is a
hygroscopic, yellowish powder, freely soluble in water & soluble in methanol[1] having Mol.
Wt. 512.94 g/mol[2]. It is a wide range of effective semisynthetic[3] long-acting hydrochloride
hemiethanol hemihydrate of Doxycycline got from Oxytetracycline[4, 5] having considerably
more dissolvability power than doxycycline monohydrate, because of which it is broadly used
in drug production[6]. It shows broad-spectrum effectiveness towards gram +ve and gram -ve
microorganisms, including Bartonella, Streptococcus Pyogenes, Hemoplasma, Spirochetes,
Chlamydia Elis, Enterococci, Ehrlichia, Actinomyces sp., Anaplasma Nocardia, Toxoplasma,
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Plasmodium Species, Mycoplasma, Protozoa, and a few anaerobic varieties[7]. It inhibits
matrix metalloproteinases (MMP's)[8] which are engaged with various immune and
inflammatory reactions, for example, periodontitis, gum disease, degenerative rheumatic
illnesses, and degenerative vascular issues[9, 10] consequently it is utilized to cure
periodontitis and related risk problems like respiratory issues[11], diabetes mellitus[12],
cardiovascular problems[13], foetopahtic changes in incubation period[14], alveolar bone
misfortune[15] and so on. DOXH is acted by inhibiting protein synthesis and the alteration of
cytoplasmic film penetrability inside the susceptible organism[5]. DOXH is additionally used
in the cure and treatment of relapsing fever, acne, chronic prostatitis, respiratory infections,
sinusitis, Lyme sickness, syphilis, exacerbations of bronchitis in patients with COPD,
brucellosis, chronic intestinal amoebiasis, non-gonococcal urethritis, cervicitis, urinary tract
infection, chlamydia, provocative pelvic illness, rickettsial diseases, and threatening radiations
that are regularly connected with malignancies[16] and ovary, lung & breast cancer, exact
treatment (for beginning therapy of all blended disease) and other sexually transmitted
diseases[4, 5, 17]. Indian Pharmacopeia[18], British Pharmacopeia[19], United States
Pharmacopeia[20], European Pharmacopeia[21], and Japanese Pharmacopeia[22] having
DOXH official monograph.
Levofloxacin hemihydrate (LVXH), C36H42F2N6O9 (CAS No. 138199-71-0), is an off-
white to yellow, odorless translucent powder, sparingly soluble in water & methanol, having
Mol. wt. 740.7 g/mol.[23] LVXH is an L-isomer of ofloxacin[24], second-generation synthetic
fluoroquinolones alluded to as respiratory quinolone[25]. It shows broad-spectrum bactericidal
effectiveness towards gram +ve and gram -ve aerobes[26, 27] shows more prominent
movement towards gram-positive microbes yet lesser action toward gram-negative
microorganisms. It hinders the supercoiling movement of bacterial DNA gyrase and
topoisomerase – II and IV, fundamental proteins in the multiplication of bacterial DNA, which
brings about the stopping of DNA replication. Topoisomerase IV is necessary to separate DNA
that has been imitated preceding bacterial cell division[24]. Bacteria are unable to divide due
to an interrupted cell division cycle as DNA is not separated. As supercoiling of DNA is caused
by DNA gyrase, it will fit in the recently shaped cells[28]. The said mechanisms are responsible
for the killing of the bacteria. LVXH has application in the treatment of airway infections[29],
conjunctivitis, urinary tract infections, acute bacterial sinusitis, chronic bronchitis, chronic
prostatitis, mastitis, community-acquired and nosocomial pneumonia, abdominal infections,
gastroenteritis, topical infections, and acute pyelonephritis[30–32]. It is a principal drug in the
management of MDR tuberculosis[33]. It is likewise used to treat irresistible loose bowels
brought about by E. coli, Campylobacter jejuni, and Shigella microorganisms. It is official in
the United States pharmacopeia[34]. Chemical Structures and IUPAC names of Doxycycline
hyclate and Levofloxacin hemihydrate were given in Table 1. The literature survey uncovers a
few logical techniques for Doxycycline estimation viz. UV method[35, 36], Derived
spectroscopic methods[37], UV spectrophotometric absorption ratio method[38],
Chemiluminescence[39], HPLC[40–42], HPLC-UV[43], Thin-layer chromatography[44],
HPTLC[45], RP-HPLC[46–48], Optical fiber sensor[49], Sequential injection
chromatographic analysis[50], Lanthanide sensitized luminescence[51], IR spectroscopy[52],
Solid surface phosphorescence[53], Flow-injection analysis/merging zones technique[54],
HPLC-DAD and LC–ESI–MS analysis[3], Internal solid contact sensor based on conducting
polypyrrole[55], HPLC–UV and LC-MS–MS[56], HPLC-MS[57], Micellar electrokinetic
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capillary chromatography[58], Ion-selective electrode potentiometry[59], Chemometric-
Assisted Spectrophotometric Method[60], Capillary electrophoresis[61], Fluorimetry[62],
TLC-fluorescence scanning densitometry[63], Titrimetry[64], Cyclodextrin based
fluorosensor[65] and techniques for Levofloxacin estimation viz. UV method[66–68],
HPLC[69], RP-HPLC[70–73], HPTLC[74], HPLC–FLD–DAD[75], HPLC-MS[76], Micellar
liquid chromatography[77, 78], Spectrofluorometric methods[79, 80], UPLC[81], UPLC-
MS/MS[82], HPLC with UV detection[83, 84], Vibrational Spectroscopy[85], Fluorometric
detection[86], Atomic Absorption Spectrometry[87], HPLC - Tandom mass spectrometry[88],
RP-UFLC[89], Capillary electrophoresis with electrochemiluminescence detection[90],
Adsorptive square-wave anodic – stripping voltammetry[91], Chemiluminescence[92],
Hydrotropy and first derivative UV spectroscopy[93], Conductometric, Potentiometric[94] and
Flow injection analysis method[95], which are monotonous, awkward, slow processing time,
expensive process due to need of costly reagents, use high degree temperatures and some buffer
solutions, require extraction, have been accounted for quantitative assessment of DOXH and
LVXH alone and in combine dosage forms. The standard procedure is given in the British
Pharmacopoeia[96].
Table 1. Structure and IUPAC Name of Doxycycline hyclate[97] and Levofloxacin hemihydrate[98].
Drug Structure IUPAC Name
Doxycycline
(4S,4aR,5S,5aR,6R,12aR)-4-
(dimethylamino)-1,5,10,11,12a-
pentahydroxy-6-methyl-3,12-dioxo-
4a,5,5a,6-tetrahydro-4H-tetracene-2-
carboxamide;ethanol;hydrate
Levofloxacin
(2S)-7-fluoro-2-methyl-6-(4-methylpiperazin-
1-yl)-10-oxo-4-oxa-1-azatricyclo[7.3.1.0]trideca-5(13),6,8,11-
tetraene-11-carboxylic acid
All of these strategies are less delicate, including tedious systems like warming and
extraction, exorbitant reagents, etc. Also, reported techniques were not much cost-effective as
far as the above factors, so the current investigation was embraced. The thorough literature
study uncovered that none of the most perceived pharmacopeias or any journals includes
simultaneous determination technique for DOXH and LVXH in combination by UV/Visible
spectroscopy. Obvious spectrophotometry, due to straightforwardness, cost-effectivity,
selectivity, reasonable exactness, and accuracy, have stayed serious in a period of
chromatographic methods for drug examination. So, it was felt fundamental to build up a
system that will serve as a solid, precise UV technique for the simultaneous estimation of
DOXH and LVXH. The current examination was completed in the perspective of setting up a
simple, quick, precise, cost-effective, and robust UV technique for simultaneous determination
of DOXH and LVXH in combination drug products.
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The main objective of the current study is to develop and validate the UV-Visible
spectrophotometric techniques for the quantitative assessment of DOXH and LVXH in a
synthetic mixture which is also applicable for their combined pharmaceutical formulations to
build up exactness and precision of determining results without using expensive reagents and
instrumentation.
2. Materials and Methods
Analytically pure free samples of DOXH and LVXH were procured from Micro Labs
Limited, Bangalore and The Madras Pharmaceuticals, Karappakam, Chennai, respectively.
Double distilled water, methanol, and the other reagents used were of AR grade.
2.1. Instruments.
A double beam UV-Visible spectrophotometer (Shimadzu UV-1800), 10mm matched
quartered cell with UV-probe software, pH meter, Ultra sonicator, and calibrated Precision
balance model Citizen Cy220 (0.1mg sensitivity) were used for the experimental purpose.
2.2. Solvent system.
After several trial-and-error experimentations on various solvents in different
proportions, finally Distilled water and Methanol mixture in the ratio 80:20 was selected as a
solvent system for method development procedure considering solubility of both the drugs, i.e.,
DOXH and LVXH in the respective solvent.
2.3. Preparation of Phosphate Buffer pH 6.8.
Dissolve 28.80gm of Disodium Hydrogen Phosphate and 11.45gm of Potassium
Dihydrogen Phosphate in the required quantity of selected solvent system to produce 1000
ml.[99]
2.4. Standard stock solution of DOXH.
A precisely weighed amount of DOXH (10 mg) was taken in a 10ml volumetric flask,
dissolved, and diluted with prepared Phosphate Buffer pH 6.8 to acquire a working-standard
solution of 1000μg/ml concentration. From this solution adequate amount was pipetted out and
diluted with the prepared Phosphate Buffer pH 6.8 to acquire working dilutions in a
concentration range of 2 to 20μg/ml.
2.5. Standard stock solution of LVXH.
A precisely weighed amount of LVXH (10 mg) was taken in a 10ml volumetric flask,
dissolved, and diluted with prepared Phosphate Buffer pH 6.8 to acquire a working-standard
solution of 1000μg/ml concentration. From this solution adequate amount was pipetted out and
diluted with the prepared Phosphate Buffer pH 6.8 to acquire working dilutions in a
concentration range of 2 to 20μg/ml.
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2.6. Mixed standard stock solution.
The mixed standard stock solution of DOXH and LVXH in the ratio of 1:1 was prepared
from standard stock solutions (1000μg/ml) using Phosphate Buffer pH 6.8.
2.7. Absorption maxima and Iso-absorptive point determination.
The standard solution (10μg/ml) was examined in the range mode over the scope of
200-400 nm utilizing a 100nm/min scanned speed, 1 cm quartz cell for absorption maxima
determination, and overlain spectra preparation.
2.8. Calibration curve preparation.
Working dilutions of 2 - 20 μg/ml concentrations of DOXH and LVXH were prepared
using Phosphate Buffer pH 6.8. Absorbance was recorded for DOXH and LVXH at 273nm and
287nm, respectively, and a standard calibration curve was prepared.
2.9. Absorbance additivity study.
Absorbance additivity data was obtained by measuring the absorbance of working
standard dilutions of individual drugs (2μg/ml) and their mixture (1:1) at selected wavelengths,
i.e., 273nm and 287nm.
2.10. Absorptivity determination.
The absorbances were estimated at the chosen wavelengths, i.e., 273nm and 287nm that
are absorption maxima's of DOXH and LVXH individually and absorptivity (A 1%, 1 cm) of
DOXH and LVXH at λmax, i.e., 273nm and 287nm, respectively, were calculated from the
mean of three different absorbance readings by using the following formula.
A (1%, 1 cm) = Absorbance/Concentration (g/100ml)
Finally, the mean of all absorptivity values was calculated as ax and ay at 273nm and
287nm, respectively.
2.11. Simultaneous equation method development.
On the off chance that a mixture has two different absorbing drugs, which shows
absorbance at the λmax of the each other, it very well might be feasible to estimate the two
drugs by the procedure of simultaneous equation. Two wavelengths chosen for the technique
are λ1 - 273nm and λ2 - 287nm that is absorption maxima's of DOXH and LVXH individually
in Phosphate Buffer pH 6.8. Concentrations in the given mixture were estimated by using the
following equations-
By considering DOXH and LVXH having concentrations, Cx and Cy respectively, in a
synthetic mixture, the following two equations were designed at λ1 (λmax – 273nm) and λ2
(λmax – 287nm) as:
At λ1 (λmax – 273nm), A1 = ax1 b Cx + ay1 b Cy……………..…Equ. 1
At λ2 (λmax – 287nm), A2 = ax2 b Cx + ay2 b Cy………………..Equ. 2
where,
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Cx & Cy = DOXH and LVXH Concentrations respectively.
A1 & A2 = Absorbance of DOXH and LVXH synthetic mixture at 273 nm & 287 nm
respectively.
ax1 & ax2 = DOXH Absorptivity value at 273 nm & 287 nm respectively.
ay1 & ay2 = LVXH Absorptivity value at 273 nm & 287 nm respectively.
b = 1, for 1 cm cell measurement
Rearranging Equ. 2
Cy = A2 - ax2 Cx / ay2 ………………..Equ. 3
Substitute this value of Cy in Equ. 1 & after rearranging we get:
Cx = A1 ay2 - A2 ay1 / ay2 ax1 - ax2 ay1………………..Equ. 4
Cy = A1 ax2 - A2 ax1 / ax2 ay1 - ax1 ay2……………..…..Equ. 5
2.12. Validation protocol.
ICH Q2B guidelines were followed for the Linearity, Range, Precision, Specificity,
LOD, LOQ, Sensitivity, and Accuracy studies which were performed for the validation of the
proposed method. [100, 101].
2.12.1. Linearity and range.
Various effective concentrations of DOXH and LVXH standard solution were
investigated for assessing the linearity & range[102].
2.12.2. Precision.
The closeness of agreement (level of dispersing) between a series of determinations
obtained from multiple sampling of the similar homogeneous sample under the endorsed
conditions is known as precision. Precision was completed by performing inter-day, intraday,
and different analysts on the same day, utilizing 10μg/ml concentration. In an intraday
variation, the absorbances were estimated multiple times in a day. In Inter-day variation, the
sample was analyzed on three successive days. %RSD values were determined, which ought
to be under 2 %[103, 104].
2.12.3. Specificity.
Spectra of both the standard solution and the prepared drug sample solutions for the
study was recorded to affirm the specificity of the proposed analytical method [105, 106].
2.12.4. Limit of detection.
The minimum concentration of a sample that can be estimated but not necessarily as an
exact value is known as the Limit of detection (LOD). It can be obtained by determining the
signal-to-noise ratio, using International Conference on Harmonization (ICH) guidelines Q2
(R1) formula as given below:
LOD = 3.3 X σ/s
where, σ = Standard deviation of the y-intercept of regression lines,
S = Slope of a calibration curve
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2.12.5. Limit of Quantitation.
The minimum concentration of a sample that can be quantitatively estimated with
suitable precision and accuracy is known as the Limit of quantification (LOQ).
LOQ= 10 X σ/s
where, σ = Standard deviation of the y-intercept of regression lines,
S = Slope of a calibration curve
2.12.6. Sensitivity.
Sensitivity refers to the smallest amount that can be precisely estimated. It additionally
shows the limit of the technique to record or gauge small variations in concentrations. On
account of spectrophotometric strategies, a parameter known as "Sandell's Sensitivity" is
utilized to assess the method's sensitivity. It is the amount needed to give an absorbance of
0.001 units in one square centimeter way.
2.12.7. Accuracy.
The accuracy determination was performed using the standard addition method. The
pre-quantified 10μg/ml sample solution of DOXH and LVXH were spiked with an extra 80,
100, and 120% of the standard DOXH and LVXH pure drug. Absorbances were measured at
273nm, and 287 nm (λmax of DOXH and LVXH, respectively), and the concentration of both
drugs can be determined. These mixtures were analyzed, and %RSD values were estimated by
the proposed developed method. The procedure was repeated thrice. The percentage recovery
of the samples, %RSD, and the percentage were calculated at each concentration level[104,
107].
3. Results and Discussion
The proposed developed novel analytical method was found to be sensitive, simple,
economical, accurate, and precise. The given method has been validated according to ICH
guidelines.
3.1. Absorption maxima and Iso-absorptive point determination.
DOXH and LVXH showed an absorbance maxima peak at λmax 273nm and 287nm
separately and were selected to develop the simultaneous equation method. Overlain spectra of
the DOXH and LVXH depicted the occurrence of two peaks at 273nm and 287nm.
Additionally, an iso-absorptive point was observed at 280nm (Figure 1).
3.2. Calibration curve preparation.
The absorbance of DOXH is obtained in a range of 0.155 to 1.073 at 273nm, and for
LVXH is obtained in a range of 0.123 to 1.220 at 287nm. A standard calibration curve was
obtained linear with r2 estimation of 0.9999 and 0.9998. (Table 2 ) (Figure 2)
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(a)
(b)
LEVOFLOXACIN - Raw Data
nm.
200.00 250.00 300.00 350.00 400.00
Abs.
0.664
0.600
0.400
0.200
0.000
-0.055
DOXYCYCLIN2 - Raw Data
nm.
200.00 250.00 300.00 350.00 400.00
Abs.
0.839
0.600
0.400
0.200
-0.023
LEVOFLOXACIN - Raw Data
nm.
200.00 250.00 300.00 350.00 400.00
Abs.
0.664
0.600
0.400
0.200
0.000
-0.055
DOXYCYCLIN2 - Raw Data
nm.
200.00 250.00 300.00 350.00 400.00
Abs.
0.839
0.600
0.400
0.200
-0.023
λmax - 287.20nm
λmax - 273.40nm
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(c)
Figure 1. (a) Spectra of Doxycycline hyclate (λ max- 273nm); (b) Levofloxacin hemihydrate (λ max- 287nm);
(c) Overlain Spectra of Doxycycline hyclate (λ max- 273nm) and Levofloxacin hemihydrate (λ max- 287nm)
showing the iso-absorptive point at 280 nm.
Table 2. Calibration curve absorbance readings and Absorptivity of DOXH and LVXH.
Sr. No. Conc.
(µg/ml)
Doxycycline hyclate Levofloxacin hemihydrate
Absorbance Absorptivity Absorbance Absorptivity
273nm 287nm 273nm 287nm 273nm 287nm 273nm 287nm
1 2 0.155 0.054 775 270 0.031 0.123 155 615
2 4 0.248 0.137 620 342.5 0.072 0.249 180 622.5
3 6 0.371 0.250 618.3 416.6 0.174 0.368 290 613.3
4 8 0.475 0.344 593.7 430 0.255 0.494 318.7 617.5
nm.
200.00 250.00 300.00 350.00 400.00
Abs.
0.844
0.800
0.600
0.400
0.200
0.000
-0.071
ISOABSORPTIVE
POINT
280.40nm
DOXYCYCLIN
273.40nm
LEVOFLOXACIN
287.20nm
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Sr. No. Conc.
(µg/ml)
Doxycycline hyclate Levofloxacin hemihydrate
Absorbance Absorptivity Absorbance Absorptivity
273nm 287nm 273nm 287nm 273nm 287nm 273nm 287nm
5 10 0.564 0.423 564 423 0.376 0.608 376 608
6 12 0.662 0.511 551.6 425.8 0.456 0.727 380 605.8
7 14 0.751 0.590 536.4 421.4 0.524 0.856 374.2 611.4
8 16 0.876 0.705 547.5 440.6 0.603 0.962 376.8 601.2
9 18 0.982 0.801 545.5 445 0.694 1.089 385.5 605
10 20 1.073 0.882 536.5 441 0.781 1.220 390.5 610
Mean (ax) 588.85 405.59 Mean (ay) 322.67 610.97
Table 3. Absorbance readings of Doxycyclin hyclate:Levofloxacin hemihydrate (1:1) synthetic mixture.
Sr. No. Conc.
(µg/ml)
Absorbance
273nm 287nm 280nm
1. 2:02 0.083 0.0785 0.0655
2. 4:04 0.14 0.173 0.16
3. 6:06 0.2425 0.279 0.266
4. 8:08 0.325 0.379 0.366
5. 10:10 0.42 0.4655 0.4525
6. 12:12 0.499 0.559 0.546
7. 14:14 0.5675 0.653 0.64
8. 16:16 0.6595 0.7535 0.7405
9. 18:18 0.748 0.855 0.842
10. 20:20 0.827 0.951 0.938
(a)
3.3. Absorbance additivity study.
This study shows the significant difference between the theoretical and practical
absorbance of a synthetic mixture (Table 4).
at λ max- 273nm: y = 0.0511x + 0.054
R² = 0.999
0
0.2
0.4
0.6
0.8
1
1.2
0 5 10 15 20 25
Ab
sorb
an
ce
Concentration (µg/ml)
Doxycycline hyclate
273nm
287nm
280nm
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(b)
(c)
Figure 2. Calibration Curve of (a) Doxycycline hyclate; (b) Levofloxacin hemihydrate; (c) Doxycyclin
hyclate:Levofloxacin hemihydrate (1:1) synthetic mixture at 273 nm, 287 nm & 280 nm.
Table 4. Absorbance additivity study.
Sr. No. Absorbance Theoretical Absorbance
of Mixture
Practical Absorbance
of Mixture DOXH LVXH
273nm 287nm 273nm 287nm 273nm 287nm 273nm 287nm
1. 0.155 0.054 0.031 0.123 0.186 0.177 0.184 0.174
2. 0.156 0.052 0.033 0.124 0.189 0.176 0.187 0.175
3. 0.156 0.053 0.031 0.121 0.187 0.174 0.186 0.172
4. 0.153 0.054 0.03 0.123 0.183 0.177 0.181 0.174
5. 0.155 0.056 0.032 0.121 0.187 0.177 0.185 0.173
at λ max- 287nm: y = 0.0604x + 0.0053
R² = 0.9998
0
0.2
0.4
0.6
0.8
1
1.2
1.4
0 5 10 15 20 25
Ab
sorb
an
ce
Concentration (µg/ml)
Levofloxacin
273nm
287nm
280nm
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 5 10 15 20 25
Ab
sorb
an
ce
Concentration (µg/ml) (1:1)
Doxycyclin hyclate : Levofloxacin hemihydrate (1:1)
synthetic mixture
273nm
287nm
280nm
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3.4. Absorptivity determination.
Absorptivity readings of DOXH and LVXH at 273nm and 287nm are shown in Table
2. Average absorptivity values of DOXH were found to be 588.85 at 273nm and 405.59 at
287nm. Average absorptivity values of LVXH were found to be 322.67 at 273nm and 610.97
at 287nm.
3.5. Simultaneous equation method development.
To find out the concentration of DOXH and LVXH in a synthetic mixture, the following
simultaneous equations were used to calculate the concentration of individual drugs:
For DOXH concentration measurement,
Cx = A1 ay2 – A2 ay1 / ay2 ax1 – ax2 ay1
For LVXH concentration measurement, use Equ. 3 i.e.
Cy = A2 - ax2 Cx / ay2
This equation is further used and validated for a synthetic mixture's DOXH (Cx) and
LVXH (Cy).
3.6. Validation protocol.
3.6.1. Linearity and range.
Selected methods showed linearity within the 2-20 µg/ml concentration range for
DOXH and LVXH, and the correlation coefficient values, r2 for UV spectroscopy, were 0.9999
and 0.9998 at λmax 273nm and 287nm, respectively. Absorbance vs. concentration relation of
DOXH and LVXH shows linear correlation. The linearity of the connection among absorbance
and concentration was dictated by plotting the calibration curve for DOXH and LVXH
separately shown in Figure 2 (a) & (b), respectively. The results of the linearity are given in
Table 2.
3.6.2. Precision.
Intra-day precision of the proposed method was found to be 0.767 % RSD for DOXH
and 0.507 % RSD for LVXH, Inter-days precision of the proposed method was found to be
0.563 % RSD for DOXH, and 0.532 % RSD for LVXH, Precision analysis by the different
analyst of the method was found to be 0.440 % RSD for DOXH and 0.708 % RSD for LVXH
(Table 5).
Table 5. Precision analysis by Intraday, Interday, and Different Analyst parameters.
Sr. No. Intraday Interday Different Analyst
DOXH LVXH DOXH LVXH DOXH LVXH
1. 100.23 100.68 102.31 100.13 102.51 101.29
2. 101.71 100.48 101.54 101.17 101.35 101.48
3. 100.65 101.36 102.38 100.68 101.48 102.51
4. 102.41 101.51 101.14 100.25 101.64 101.48
5. 101.54 100.18 102.68 101.54 101.27 100.25
Mean 101.30 100.84 102.01 100.75 101.65 101.40
±SD 0.777 0.511 0.575 0.536 0.447 0.718
% RSD 0.767 0.507 0.563 0.532 0.440 0.708
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3.6.3. Specificity.
The spectra obtained from the DOXH and LVXH solution were discovered to be
identical to those acquired for the standard solution (Fig. 1).
Table 6. Specificity analysis at different parameters.
Sr. No. Parameters DOXH* LVXH*
1. Room Temp. 102.21 101.35
2. Acid (0.1N HCL) 83.24 74.36
3. Alkali (0.1N NaOH) 91.51 90.21
4. Oxide (3% H2O2) 85.64 87.35
5. Heat 24hr (60oC) 95.37 92.54
*mean of three determination
3.6.4. Limit of Detection
The estimation of LOD values of DOXH and LVXH were found to be 1.41 and 0.63
μg/ml, respectively (Table 9).
3.6.5. Limit of Quantitation.
The estimation of LOQ values of DOXH and LVXH were found to be 4.30 and 1.92
μg/ml, respectively (Table 9).
3.6.6. Sensitivity.
Sensitivity analysis shows promising results in terms of method validation. Sandell's
sensitivity was discovered to be adequate and acceptable (Table 9).
3.6.7. Accuracy.
Percent recovery for DOXH at recovery level of 80% was found to be 99.7, at recovery
level of 100% was found to be 99.66, and at recovery level of 120% was found to be 99.69.
Table 7. Recovery analysis of proposed method at three different recovery levels.
Sr. No. Recovery
level
Amount of pure drug
added (µg/ml)
Amount of drug estimated
(µg/ml)
Percent drug estimated
DOXH LVXH DOXH LVXH DOXH LVXH
1. 80% 8 8 7.98 7.97 99.75 99.62
8 8 7.98 7.97 99.75 99.62
8 8 7.97 7.96 99.62 99.5
Mean 99.7 99.58
±SD 0.058 0.058
% RSD 0.059 0.059
2. 100% 10 10 9.97 9.96 99.7 99.6
10 10 9.97 9.96 99.7 99.6
10 10 9.96 9.98 99.6 99.8
Mean 99.66 99.66
±SD 0.047 0.094
% RSD 0.047 0.094
3. 120% 12 12 11.96 11.97 99.66 99.75
12 12 11.96 11.96 99.66 99.66
12 12 11.97 11.94 99.75 99.5
Mean 99.69 99.63
±SD 0.039 0.103
% RSD 0.039 0.104
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Percent recovery for LVXH at recovery level of 80% was found to be 99.58, at recovery
level of 100% was found to be 99.66, and at recovery level of 120% was found to be 99.63
(Table 7). In this method, the amount of the individual drug was estimated by solving the
simultaneous equation at 273nm and 287nm using the respective absorptivity value.
Table 8. Analysis of laboratory synthetic mixture by the proposed method.
Sr. No. Amount of drug taken for
assay (µg/ml)
Amount of drug estimated
(µg/ml)
Percent drug estimated
DOXH LVXH DOXH LVXH DOXH LVXH
1. 10 10 09.97 09.98 99.7 99.8
2. 10 10 09.98 10.12 99.8 101.2
3. 10 10 10.1 10.11 101 101.1
4. 10 10 10.11 09.97 101.1 99.7
5. 10 10 09.97 10.11 99.7 101.1
Mean 100.26 100.58
±SD 0.646 0.679
% RSD 0.645 0.675
Table 9. Optical properties and validation parameters of Doxycycline hyclate and Levofloxacin hemihydrate.
Sr. No. Parameters DOXH LVXH
1. λ max 273nm 287nm
2. Beer Lambert’s linear Conc. range (µg/ml) 2 - 20 2 - 20
3. Mean Absorptivity values 588.85 610.97
4. Sandell’s sensitivity 0.294 0.237
5. Regression equation y = 0.0511x + 0.054 y = 0.0604x + 0.0053
6. Correlation coefficient (r2) 0.9999 0.9998
7. Slop (m) 0.0511 0.0604
8. Intercept (c) 0.054 0.0053
9. SE of Intercept 0.0069 0.0036
10. SD of Intercept 0.0219 0.0116
11. LOD (µg/ml) 1.41 0.63
12. LOQ (µg/ml) 4.30 1.92
13. Intraday precision % RSD 0.767 0.507
14. Interday precision % RSD 0.563 0.532
15. Precision by different analysist % RSD 0.440 0.708
16. Percent Recovery (at 80% level) 99.7 99.58
17. Percent Recovery (at 100% level) 99.66 99.66
18. Percent Recovery (at 120% level) 99.69 99.63
Overlain spectra of the DOXH and LVXH depicted an iso-absorptive point observed at
280nm. For method development, two absorbance maxima, i.e., λmax 273nm and 287nm, were
selected at which DOXH and LVXH show the linear relationship between absorption and
concentration with r2 values of 0.9999 and 0.9998 in a range of 2-20 µg/ml concentration.
Correlation coefficients of the regression (r2) values are used to validate the linearity of the
calibration curves, and a higher value of r2 indicates the precision and acceptable linearity of
the developed method. Lower % RSD values in all precision study parameters were below 1%,
which means within a range specified by ICH, which reflects the good, acceptable accuracy,
preciseness, and repeatability/reproducibility property of the proposed developed method. The
addition of DOXH and LVXH standard solutions for recovery analysis did not change spectra'
qualities, which confirms the proposed method's validity. Lower values of LOD & LOQ
confirm the acceptable sensitivity of the proposed method. Sandell's sensitivity was discovered
to be adequate, and this shows that extremely less measure of the two medications can be
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successfully recognized by this technique. Greater recovery values indicate the acceptable
repeatability and accuracy of the proposed method.
4. Conclusions
Regression analysis (Linearity and Range) for both the drugs was > 0.999, indicating
the validated method's precision. Repeatability and inter and intra-day precision were studied
where %RSD was found to be less than 1 for both drugs. A lower value of LOD and LOQ
confirms the sensitivity of the specified method. System suitability, the mean % RSD was
found to be less than 1 for both DOXH and LVXH, which was found to be well within the
acceptable limit.
All these factors lead to the conclusion that the above-validated method mentioned in
this paper for simultaneous estimation of DOXH and LVXH by the spectrophotometric
technique can be recommended for regular quality control analysis in the synthetic mixture and
their combined pharmaceutical dosage forms, and it was found to be simple, accurate, precise,
sensitive, reproducible, economical and rapid. The solvents used for the proposed methods
were inexpensive and simple to prepare. This method was adopted to be used in a quality control
study for regular drug analysis.
Funding
This research received no external funding.
Acknowledgments
Authors are thankful to Micro Labs Limited, Bangalore and The Madras Pharmaceuticals,
Karappakam, Chennai for providing gift samples of DOXH and LVXH, respectively. Authors
are also thankful to the Principal and management of Priyadarshini J. L. College of Pharmacy,
Nagpur- 440016 Dist-Nagpur (M.S.) India, for providing necessary facilities to carry out the
research work.
Conflicts of Interest
The authors declare no conflict of interest.
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